KR102263709B1 - Conduction type sluice device equipped with eccentric roller rotating shaft - Google Patents

Abstract

The present invention relates to a conductive sluice device which selectively opens and closes a river channel. More specifically, the device comprises: a guide roller unit which supports load between a rotation guide unit and guides rotation of the sluice unit; and an eccentric roller rotating shaft enabling an eccentric roller of the guide roller unit to be configured to change a position of a rotating shaft thereof.

Description

Conduction type sluice device equipped with eccentric roller rotating shaft

The present invention relates to a conductive sluice device that selectively opens and closes a river channel, and more particularly, supports a load between a rotation guide part and a sluice part, and a guide roller part for guiding the rotation of the sluice part is provided, It relates to a conduction type sluice gate device provided with an eccentric roller rotating shaft configured to allow the eccentric roller of the guide roller to change the position of the rotating shaft.

In general, a sluice gate installed in a drainage channel of a river or embankment to control the amount of water stored is opened and closed automatically or manually to store or discharge water. In the case of an automatic sluice gate, the opening and closing operation of the sluice gate is usually performed by a hydraulic cylinder.

And looking at the configuration example of the hydraulic inverted sluice gate of a conventional type to open and close the sluice gate by means of a hydraulic cylinder, the sluice gate body and the rotation shaft are integrally formed on both sides of the sluice gate body, and the rotation shaft extends into the housing It is rotatably installed in the form of penetrating the shaft hole of the fixed bracket, one end of the connecting link is connected to the rotating shaft located in the fixed bracket, and the other end of the connecting link is in a configuration in which the tip of the operating rod of the hydraulic cylinder is connected by a pivot. On both sides of the sluice gate, the sluice gate is opened and closed by means of turning the sluice gate by the expansion and contraction operation of the hydraulic cylinder.

As one of the technologies for such a sluice gate opening and closing device, Korean Patent Publication No. 10-1380998 (hereinafter referred to as a prior art) is disclosed.

In the prior art, the sluice gate is operated according to the operation of the cylinder, and as a large load is applied to the connecting link connecting the cylinder and the sluice gate, durability is deteriorated and frequent replacement is required.

In addition, in the prior art, when water pressure is continuously applied due to poor durability of the sluice gate, the sluice gate may be twisted, and if the sluice gate is bent by its own weight, opening and closing of the sluice gate is not performed smoothly. A problem arises that cannot be

Registered Patent Publication No. 10-1380998 2014.03.27.

The present invention was created to solve the problems of the prior art, and the problem to be solved in the present invention is to support a load between the rotation guide part and the sluice part, but a guide roller part for guiding the rotation of the sluice part is provided It is to provide a conductive sluice device provided with an eccentric roller rotating shaft configured to enable the eccentric roller of the guide roller to change the position of the rotating shaft.

The present invention provides a conductive sluice gate device for selectively opening and closing a water channel of a river, comprising: a sluice gate part 100 extending in a left and right direction and provided to cross the water channel; a rotation guide part 200 extending in the left and right direction so that the rear end and both ends of the sluice gate 100 are hingedly fastened so that the sluice gate 100 is rotated in the vertical direction; and a driving unit 400 configured to rotate the sluice gate unit 100 and provided in the rotation guide unit 200 .

At this time, the sluice part 100 includes a first surface 110 extending in the left and right directions to have a predetermined front and rear length; a second surface (120) facing the first surface (110) and spaced apart from each other by a predetermined distance in one direction so that both ends in the front and rear directions are coupled to the first surface (110); and a hinge portion 130 provided to seal between the left and right ends of the first surface 110 and the second surface 120; and, when the sluice gate 100 is in a state in which the water channel is opened, The front end faces the inflow direction of the river water, the rear end faces the discharge direction, and the second surface 120 is provided so that it faces upward.

In addition, the hinge unit 130 includes a hinge plate 132 that seals the space between the first surface 110 and the second surface 120, but the rear end is provided to protrude outward; and a hinge protrusion 131 that is through-coupled to the groove formed on the rear end side of the hinge plate 132 .

On the other hand, in the sluice part 100, the first end is made in the form of a pipe extending in the left and right direction so that the front ends of the first surface 110 and the second surface 120 are coupled to the outer circumferential surface of the pipe. coupling member 141; and a second end coupling member 142 that is composed of a frame in which an 'H'-shaped beam extends in the left and right directions, so that the first surface 110 and the second surface 120 are respectively coupled to the outside of the pair of flanges. The end coupling member 140 including; is further provided.

In this case, the rotation guide part 200 includes a base part 210 provided on the bottom surface of the water channel at the lower end of the sluice gate part 100 while a plurality of frames (steel materials) form a grid; And the support part 230 is provided at both ends in the left and right direction of the sluice part 100, the support part 230 for hinge-fastening both ends of the sluice part 100 in the left and right directions.

In addition, the sluice part 100 further includes a first auxiliary rotating protrusion 170 protruding outwardly from the rear end of the second end coupling member 142 , and the rotation guide unit 220 includes the The first auxiliary rotating protrusion 170 of the sluice gate 100 and the first auxiliary rotating protrusion 170 of the sluice gate 100 are hinged so as to be provided on the transverse steel material 211 disposed at the rearmost side of the base portion 210, and a plurality of pieces are arranged to be spaced apart in the left and right directions 2 to further include an auxiliary rotating protrusion 220 .

On the other hand, the driving unit 400, one end is hinged with the inner bottom surface of the support unit 230 of the rotation guide unit 200, the other end is a cylinder unit 410 configured to take out the rod; The support part consists of a pair of plates spaced apart from each other by a predetermined distance in the left and right directions in a state in which a rotation groove is formed on the surface, and the hinge protrusion 131 of the sluice part 100 is hinged to the rotation groove so as to be axially rotatable. a drive shaft bracket 420 provided on the inner bottom surface of the 230; and a rotation member 430 that is configured to be rotatable in the vertical direction according to the withdrawal of the cylinder portion 410 rod, and is coupled to the hinge protrusion 131 while being disposed between the pair of drive shaft brackets 420 . ); should be included.

In addition, between the rotation guide part 200 and the sluice part 100, an eccentric roller 313 of which the position of the rotation shaft can be changed is included, and a load support provided on the rotation guide part 200 is provided. roller unit 310; A guide rail portion 320 comprising a rail member 323 formed to be coaxial with the eccentric roller 313 and extending in the circumferential direction at a position spaced a predetermined distance outward from the outer circumferential surface of the eccentric roller 313 ); and a guide roller part 330 provided on the rear end side of the sluice gate part 100 so as to be rotated along the surface of the rail member 323 .

At this time, the load supporting roller unit 310 includes a load supporting bracket 311 provided at the upper end of the base unit 210 of the rotation guide unit 200 ; an eccentric roller groove 312 having an angled cross-section and penetrating through the surface of the load support bracket 311; and an eccentric roller 313 in which an eccentric protrusion 314 protrudes outward from a position eccentric to one side on both sides of the roller and is inserted and fastened to the eccentric roller groove 312 .

On the other hand, the eccentric protrusion 314 is made to have a polygonal cross section in a symmetrical shape, and the eccentric roller groove 312 has an inner bottom surface to correspond to the polygonal shape of the eccentric protrusion 314 . .

In addition, the guide rail part 320 is provided on the upper side of the load support bracket 311 in a state in which a rail center groove 322 in which the rotation shaft of the eccentric roller 313 is rotatably disposed on the upper side is formed. rail bracket (321); and a rail member 323 formed of a plate bent to have a predetermined radius and provided on an upper portion of the load support bracket 311 ; to include

On the other hand, the guide roller part 330 is provided in a face-to-face state by protruding from the rear end side of the sluice gate part 100 to the rear side, and the upper end side of the guide rail part 320 is disposed in the space between them. a guide bracket 331 being; a guide protrusion 332 protruding from the protruding end of the inner surface facing the guide bracket 331 in a direction facing each other; a guide groove 333 into which the eccentric roller 313 is inserted; and a guide roller 334 that is axially rotatably provided on the front end side of the guide protrusion 332 and is configured to be guided along the lower surface of the rail member 323 .

According to the present invention, the position of the rotation shaft can be changed between the sluice part and the rotation guide part, and as an eccentric roller is provided to guide the rotation of the sluice part, even if sagging of the sluice part occurs due to its own weight, the gap is filled. It ensures that the rotation of the sluice gate can be performed stably.

In addition, according to the present invention, a hydraulic cylinder is used as a power device for the operation of the sluice unit, and the cylinder and the sluice unit are connected by a link, so that the sluice gate can be easily operated even with a small amount of power.

1 is a view of an installation embodiment of a conductive sluice device provided with an eccentric roller rotating shaft according to the present invention.
Figure 2 is a perspective view of a conductive sluice device provided with an eccentric roller rotating shaft according to the present invention.
Figure 3a is a cross-sectional perspective view and a cross-sectional view of the sluice gate applied to the present invention.
Figure 3b is an exploded perspective view of the sluice gate applied to the present invention.
Figure 4 is a perspective view of the rotation guide applied to the present invention.
Figure 5a is an enlarged view of section A of Figure 2, a view showing a state in which the driving unit applied to the present invention closed the sluice part.
Figure 5b is a view showing a state in which the sluice gate is opened in the state 5a.
6 is a view showing an embodiment of the installation of the guide roller unit applied to the present invention.
Figure 7a is an exploded perspective view of the guide roller applied to the present invention.
Figure 7b is a perspective view of the guide roller applied to the present invention.
8 is a view showing a state of changing the position of the rotation shaft of the eccentric roller applied to the present invention.
9 is a view showing an example of using a guide roller unit applied to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in more detail with reference to the accompanying drawings.

The present invention relates to a conductive sluice device that selectively opens and closes a river channel, and more particularly, supports a load between a rotation guide part and a sluice part, and a guide roller part for guiding the rotation of the sluice part is provided, It relates to a conduction type sluice gate device provided with an eccentric roller rotating shaft configured to allow the eccentric roller of the guide roller to change the position of the rotating shaft.

1 and 2 , the present invention is configured to include a sluice gate 100 , a rotation guide 200 and a driving unit 400 .

The sluice gate 100 is for selectively opening and closing the water channel of the river, and is formed to extend in the left and right directions so as to cross the water channel.

3A and 3B, the sluice gate 100 controls the flow path by blocking the flow path of the river. The first surface 110 is formed to have a predetermined front and rear length and extends in the left and right direction, the The second surface 120 and the first surface 110 and the second surface facing the first surface 110 and disposed to be spaced apart by a predetermined distance in one direction so that both ends in the front and rear directions are coupled to the first surface 110 ( 120) includes a hinge part 130 provided to seal between the left and right ends, and when the sluice part 100 is in a state in which the water channel is opened, the front end faces the inflow direction of the river water and the rear end faces the discharge direction It is provided so that the second surface 120 faces upward.

At this time, the hinge part 130 seals the space between the first surface 110 and the second surface 120, but the rear end side of the hinge plate 132 and the hinge plate 132 are provided to protrude outward. It is configured to include a hinge protrusion 131 that is coupled through the groove formed on the rear end side of the.

On the other hand, the sluice part 100 includes a first end coupling member 141 connecting the front ends of the first surface 110 and the second surface 120 , and the first surface 110 and the second surface 120 . ) may be configured to further include an end coupling member 140 including a second end coupling member 142 for connecting the rear end.

The first end coupling member 141 is formed in the form of a pipe extending in the left and right direction, so that the front ends of the first surface 110 and the second surface 120 are coupled to the outer circumferential surface of the pipe.

On the other hand, the second end coupling member 142 is composed of a frame in which an 'H'-shaped beam extends in the left and right direction, and the first surface 110 and the second surface 120 are formed on the outside of the pair of flanges, respectively. made to be combined.

That is, as the second end coupling member 142 is provided to support the web between the first surface 110 and the second surface 120, the strength of the rear end side of the sluice part 100 can be improved. let this be

At this time, the hinge protrusion 131 is formed of a shaft extending in the left and right direction, and one end protruding through the groove of the hinge plate 132 is disposed at the rear of the second end coupling member 120 , and the other end side The sluice part 100 is arranged to protrude outward in the left and right direction.

That is, the sluice part 100 has a rotational central axis located on the rear side of the second end coupling member 120 .

The sluice gate 100 configured as described above is rotatable in the vertical direction based on the hinge protrusion 131 , and when the sluice gate 100 is rotated to the top, the first surface 110 moves into the waterway. The water channel is closed in a state facing the direction side. At this time, the sluice gate part 100 is inclined in a state in which the first end coupling member 141 faces the inflow direction side of the river water rather than the second end coupling member 142. It is provided so that it can respond more stably to the hydraulic pressure of river water.

Conversely, when the sluice gate 100 is rotated downward, the water channel is in an open state. At this time, the second surface 120 of the sluice gate 100 is in a horizontal state with the bottom surface to control the flow of the river. Do not disturb.

On the other hand, the sluice part 100 is configured to include a plurality of vertical bulkheads 150 and transverse bulkheads 160 to stably withstand the strong water pressure applied when the waterway is closed.

In detail, the longitudinal bulkhead 150 is made of a plate extending in the front-rear direction, and is provided to divide the inner space of the sluice gate 100 in a state in which both sides face in the left-right direction, and a plurality of them are spaced apart from each other by a predetermined distance in the left-right direction. to be placed

That is, the longitudinal bulkhead 150 is configured such that the front end has a curvature corresponding to the outer circumferential surface of the first end coupling member 141, and the other end is inserted and coupled between the flanges of the second end coupling member 142. configured to be disposed in the inner space of the sluice gate 100 .

On the other hand, the transverse bulkhead 160 is formed of a plate extending in the left and right directions, and a plurality of the transverse bulkheads 160 are spaced apart in the front and rear directions so as to be provided in the inner space of the sluice gate 100 .

This makes it possible to improve the internal strength of the sluice part 100 .

On the other hand, the sluice part 100 is further provided with a first auxiliary rotating protrusion 170 protruding outward from the rear end of the second end coupling member 142 .

At this time, the first auxiliary rotating protrusion 170 is configured to have the same axis of rotation as the hinge protrusion 131 so that a plurality of them are provided at the rear end of the second end coupling member 142 while being spaced apart by a predetermined distance in the left and right directions. .

Meanwhile, the rear end of the second surface 120 may further include a rotation shaft protection cap 180 extending along the periphery of the rear end of the hinge plate 132 to cover and protect the upper side of the hinge protrusion 131 .

In other words, a cross section having a predetermined arc length of the rotation shaft protection cap 180 is formed to extend in the left and right direction, and one side of the arc is coupled to the rear end of the second face 120 , and the sluice gate part 100 ) so as to cover and cover the upper side of the hinge protrusion 131 protruding to the rear side.

In addition, the sluice part 100 is formed so that one end is inserted and fastened to the rear side of the second end coupling member 142 and the other end is fastened to the rotation shaft protection cap 180, so that a plurality of auxiliary parts are arranged spaced apart in the left and right directions. It further includes a partition wall 190 .

That is, the auxiliary bulkhead 190 seals the space between the rotation shaft protective cap 180 and the second end coupling member 142 , thereby improving the rotation shaft durability of the sluice gate 100 .

On the other hand, the rotation guide part 200 is for supporting the rotation of the sluice part 100, and according to FIG. 4, is formed to extend in the left and right direction, and the rear end and both ends of the sluice gate 100 are hinged. It is configured to be such that the sluice part 100 is rotated in the vertical direction, and for this purpose, it is configured to include a base part 210 , a second auxiliary rotating protrusion 220 and a support part 230 .

The base part 210 is formed to extend in the left and right direction to be provided under the sluice part 100 , and in more detail, a plurality of frames (steel) form a lattice form on the lower end side of the sluice gate part 100 . It should be provided on the bottom surface of the waterway.

For example, the base part 210 is composed of an H-beam extending in the left and right direction, and a plurality of transverse steel materials 211 are arranged to be spaced apart in the front-rear direction on the lower bottom surface of the sluice part 100 and extend in the front-rear direction. It is composed of an H-beam that is disposed between the transverse steel members 211, and a plurality of longitudinal steel members 212 are provided to be spaced apart in the left and right directions.

That is, the base part 210 is arranged such that the transverse steel material 211 and the longitudinal steel material 212 form a lattice, and the sluice part 100 is disposed on top of the transverse steel material 211 disposed at the forefront. make it possible

At this time, the transverse steel member 211 disposed at the rear is configured to be higher than the transverse steel member 211 disposed at the front, and by stacking a plurality of transverse steel members 211 in the vertical direction, the self-weight of the sluice part 100 is reduced. make it more durable.

On the other hand, the second auxiliary rotating protrusion 220 is provided on the upper end of the base portion 210 so that the rear end side of the sluice part 100 is hinged.

In detail, the second auxiliary rotating protrusion 220 is provided on the transverse steel material 211 disposed at the rearmost side of the base part 210, and a plurality of the second auxiliary rotation protrusions 220 are arranged to be spaced apart in the left and right directions, so that the sluice gate part 100 It is made to be hinged with the first auxiliary rotary protrusion 170 of the.

On the other hand, the support part 230 is provided at both ends in the left and right directions of the sluice part 100 so that both ends of the sluice part 100 are hingedly fastened, and in more detail, the support part 230 is the base part. It is provided at both ends in the left and right directions of the 210 so that the hinge protrusions 131 of the sluice part 100 are hingedly fastened.

According to the above configuration, the rotation guide unit 200 enables the sluice gate unit 100 to rotate in the vertical direction while stably fixed.

At this time, between the sluice part and the base part 210, it is made of a flexible material that can be contracted, and is formed to extend in the left and right direction to seal the space between the rear end side of the lateral steel material 211 disposed at the rearmost side of the sluice part A packing unit 240 is further provided.

Accordingly, as the gap between the rotation guide part 200 and the sluice gate part 100 is filled, the sealing of the water channel can be made more stably.

On the other hand, according to FIGS. 5A and 5B, the driving unit 400 is for operating the sluice gate 100, and is configured to rotate the sluice gate 100 so as to be provided in the rotation guide unit 200, To this end, the driving unit 400 includes a cylinder unit 410 , a driving shaft bracket 420 , and a rotating member 430 .

One end of the cylinder part 410 is hingedly coupled to the inner bottom surface of the support part 230 of the rotation guide part 200, and the rod is drawn in and out of the other end.

The drive shaft bracket 420 is made of a pair of plates spaced apart in the left and right direction by a predetermined distance in a state in which a rotation groove is formed on the surface, so that the hinge protrusion 131 of the sluice part 100 is axially rotatable in the rotation groove. It is provided on the inner bottom surface of the support part 230 in a hinged state.

On the other hand, the rotation member 430 is configured to be rotatable in the vertical direction according to the withdrawal of the rod of the cylinder portion 410, and is disposed between the pair of drive shaft brackets 420 with the hinge protrusion 131 and To be fastened to be interlocked, for this purpose, it is configured to include a rotating shaft body 431 and a rotating plate (432).

In detail, the rotating shaft body 431 has a hinge interlocking groove formed in the central portion to which the hinge protrusion 131 of the sluice part 100 is fixed and fastened, and is axially rotatable in the space between the drive shaft bracket 420 . make it available

That is, when the rotation shaft body 431 rotates, the hinge protrusion 131 rotates in conjunction therewith, thereby allowing the sluice gate to rotate.

On the other hand, the rotation plate 432 is hinged on one side of the rod of the cylinder part 410, and on the other side, a body interlocking groove to which the rotation shaft body 431 is fixedly coupled is formed.

For this reason, when the rod of the cylinder part 410 is withdrawn, the rotation plate 432 rotates in the forward direction, and the rotation shaft body 431 linked thereto rotates in the forward direction while the sluice gate rotates in the forward direction. , which makes the waterway sealed.

Conversely, when the rod of the cylinder part 410 is drawn in, the sluice gate part rotates in the reverse direction while the rotation plate 432 rotates in the reverse direction, thereby making the water channel open.

On the other hand, as shown in FIGS. 6 to 9 , a guide roller part 300 may be further provided between the rotation guide part 200 and the sluice part 100 , and the guide roller part 300 is It is configured to include a load bearing roller unit 310 , a guide rail unit 320 , and a guide roller unit 330 .

Referring to FIG. 7 , the load support roller unit 310 includes an eccentric roller 313 in which the position of the rotation shaft can be changed, and is provided on the rotation guide unit 200 .

In detail, the load support roller part 310 is a load support bracket 311 provided on the upper side of the base part 210 of the rotation guide part 200, and the cross section is formed in an angled shape. An eccentric roller groove 312 formed through the surface of the roller and an eccentric projection 314 protruding outward from a position eccentric to one side on both sides of the roller, the eccentric roller 313 is inserted and fastened into the eccentric roller groove 312 ) should be included.

At this time, the eccentric protrusion 314 is made to have a polygonal cross section in a symmetrical shape such as a square, hexagon, or octagon, and the eccentric roller groove 312 has an inner bottom surface of the polygonal shape of the eccentric protrusion 314 . to be formed correspondingly.

Accordingly, the position of the rotation shaft of the eccentric roller 313 can be changed according to the position of the outer surface of the eccentric protrusion 314 in contact with the eccentric roller groove 312 .

Referring to FIG. 8 , the sluice gate 100 of the present invention has a phenomenon in which the left and right central portions of the sluice gate 100 are bent downward due to their own weight over time, and some of the eccentric rollers 313 . There may be a problem in that a predetermined space is generated between the guide groove 333 and the sluice gate 100 cannot stably support the rotation.

Accordingly, in the present invention, the eccentric protrusion 314 is provided at a position biased in one direction from the rotation axis of the eccentric roller 313, and as shown in FIG. 8, the eccentric protrusion 314 is rotated at a predetermined angle. When it is engaged with the eccentric roller groove 123 again, the rotation shaft of the eccentric roller 314 moves from C1 to C2, and the space between the eccentric roller 313 and the guide groove 333 is filled.

For this reason, the guide roller unit 300 allows the sluice gate 100 to rotate while always stably supporting the lower end of the sluice gate 100 .

On the other hand, the guide rail part 320 is made to have a coaxial axis with the eccentric roller 313, a rail member extending in the circumferential direction at a position spaced a predetermined distance outward from the outer peripheral surface of the eccentric roller 313 ( 323) are included.

In detail, the guide rail part 320 is provided on the upper side of the load support bracket 311 in a state in which a rail center groove 322 in which the rotation shaft of the eccentric roller 313 is rotatably disposed is formed on one upper side. It is made of a rail bracket 321 and a plate bent to have a predetermined radius, and includes a rail member 323 provided on the load support bracket 311 .

At this time, the rail member 323 is formed to protrude outward with respect to the rail bracket 321 , which is formed as a plate extending longer than the rotation radius of the sluice part 100 .

On the other hand, the guide roller part 330 is configured to rotate along the surface of the rail member 323 so as to be provided at the rear end of the sluice part 100 .

In detail, the guide roller part 330 is provided in a state in which a pair of guide rollers 330 protrude from the rear end side of the sluice gate part 100 to the rear side and face-to-face, and the upper end side of the guide rail part 320 is disposed in the space between them. A guide bracket 331 that becomes a guide bracket 331, a guide protrusion 332 protruding in a direction opposite to each other from the protruding end of the inner surface facing the guide bracket 331, and the guide protrusion 332 is recessed in the front from the rear end side A guide configured to be axially rotatably provided on the front end side of the guide groove 333 into which the eccentric roller 313 is inserted, and the guide protrusion 332, so as to be guided along the lower surface of the rail member 323. a roller 334 .

As shown in FIG. 9 according to the above configuration, in the present invention, when the sluice part 100 rotates, the guide roller 334 is in contact with the lower surface of the rail member 323 and the rail member While rotating along 323, the sluice gate 100 is rotated while the end side of the guide protrusion 332 is supported by the eccentric roller 313, so that the sluice gate 100 is stably It rotates in a supported state.

At this time, in the present invention, the position of the rotation shaft of the eccentric roller 313 can be adjusted according to the arrangement state of the eccentric roller 313, and the eccentric roller 313 and guide as the bending phenomenon of the sluice gate 100 occurs due to its own weight. When a gap is formed between the guide grooves 333 of the protrusions 332 , the arrangement of the eccentric roller 313 is changed to fill the gap, so that the sluice gate 100 can be rotated stably.

On the other hand, the guide roller part 330 is a pair of guide brackets 331 at both ends are fastened to be axially rotatable, and an auxiliary roller 335 provided in a state in contact with the upper surface of the rail member 323. may include more.

In detail, the rail member 323 is provided in a state disposed between the auxiliary roller 335 and the guide roller 334, and thus, when the sluice gate 100 is rotated, the auxiliary roller 335 ) and the guide roller 334 to rotate more stably along the rail member 323 .

Although preferred embodiments of the present invention have been described above, the scope of the present invention is not limited thereto, and it should be understood that the scope of the present invention extends to a range substantially equivalent to the embodiment of the present invention, Various modifications can be made by those of ordinary skill in the art to which the invention pertains without departing from the spirit of the invention.

100: water gate
110: first surface 120: second surface
130: hinge portion 131: hinge protrusion
132: hinge plate
140: end coupling member: first end coupling member
142: second end coupling member
150: longitudinal bulkhead 160: transverse bulkhead
170: first auxiliary rotary projection
200: rotation guide part: base part
211: transverse steel 212: longitudinal steel
220: second auxiliary rotary projection 230: support
300: guide roller unit
310: load support roller 311: load support bracket
312: eccentric roller groove 313: eccentric roller
314: eccentric process
320: guide rail 321: rail bracket
322: rail center groove 323; rail member
330: guide roller 331: guide bracket
332: guide projection 333: guide groove
334: guide roller 335: auxiliary roller
400: drive unit
410: cylinder part 420: drive shaft bracket
430: rotation member 431: rotation shaft body
432: rotation plate

Claims (12)

In the conduction-type sluice gate device for selectively opening and closing the channel of a river,
a sluice gate 100 extending in the left and right directions to cross the water channel;
a rotation guide part 200 extending in the left and right direction so that the rear end and both ends of the sluice gate 100 are hingedly fastened so that the sluice gate 100 is rotated in the vertical direction; and
a driving unit 400 configured to rotate the sluice gate unit 100 and provided in the rotation guide unit 200;
includes,
Between the rotation guide part 200 and the sluice part 100,
a load supporting roller unit 310 including an eccentric roller 313 in which the position of the rotating shaft can be changed, and provided on an upper portion of the rotation guide unit 200;
A guide rail portion 320 comprising a rail member 323 formed to be coaxial with the eccentric roller 313 and extending in the circumferential direction at a position spaced a predetermined distance outward from the outer circumferential surface of the eccentric roller 313 ); and
a guide roller unit 330 configured to rotate along the surface of the rail member 323 and provided on the rear end side of the sluice gate unit 100;
Conductive sluice gate device provided with an eccentric roller rotating shaft, characterized in that the guide roller unit 300 comprising a further provided.
The method according to claim 1,
The sluice gate 100 is
a first surface 110 made to have a predetermined front and rear length and extending in the left and right direction;
a second surface 120 facing the first surface 110 and disposed to be spaced apart by a predetermined distance in one direction so that both ends in the front and rear directions are coupled to the first surface 110; and
a hinge portion 130 provided to seal between the left and right ends of the first surface 110 and the second surface 120;
and, when the sluice part 100 is in a state in which the water channel is opened, the front end faces the inflow direction of the river water, the rear end faces the discharge direction, and the second surface 120 faces upward. Conductive sluice device with an eccentric roller rotating shaft, characterized in that it is provided.
3. The method according to claim 2,
The hinge part 130 is
a hinge plate 132 sealing the space between the first surface 110 and the second surface 120 but having a rear end protruding outward; and
a hinge protrusion 131 that is coupled through the groove formed on the rear end side of the hinge plate 132;
Conductive sluice device provided with an eccentric roller rotating shaft, characterized in that it comprises a.
3. The method according to claim 2,
In the sluice gate 100,
a first end coupling member 141 formed in the form of a pipe extending in the left and right direction so that the front ends of the first surface 110 and the second surface 120 are coupled to the outer circumferential surface of the pipe; and
a second end coupling member 142 that consists of a frame in which the 'H'-shaped beam extends in the left and right directions, so that the first surface 110 and the second surface 120 are respectively coupled to the outside of the pair of flanges;
Conductive sluice gate device with an eccentric roller rotating shaft, characterized in that the end coupling member 140 further comprising a.
3. The method according to claim 2,
The rotation guide unit 200,
a base part 210 provided on the bottom surface of the water channel at the lower end of the sluice part 100 while a plurality of frames (steel) form a grid; and
a support part 230 provided at both ends in the left and right directions of the sluice part 100 so that both ends of the sluice gate 100 are hingedly fastened;
Conductive sluice device provided with an eccentric roller rotating shaft, characterized in that it comprises a.
5. The method according to claim 4,
The sluice gate 100 is
It further comprises a first auxiliary rotating protrusion 170 protruding outward from the rear end of the second end coupling member 142,
The rotation guide unit 200,
The sluice gate part 100 is provided in the transverse steel material 211 disposed at the rearmost side of the base part 210 of the rotation guide part 200 installed on the bottom surface of the waterway, and a plurality of them are spaced apart in the left and right directions. Conductive sluice gate device provided with an eccentric roller rotation shaft, characterized in that it further comprises a second auxiliary rotation projection (220) hinged with the first auxiliary rotation projection (170) of the.
The method according to claim 1,
The driving unit 400,
a cylinder part 410 having one end hingedly fastened to the inner bottom surface of the support part 230 of the rotation guide part 200, and configured such that the rod is drawn in and out of the other end;
The support part consists of a pair of plates spaced apart from each other by a predetermined distance in the left and right directions in a state in which a rotation groove is formed on the surface, and the hinge protrusion 131 of the sluice part 100 is hinged to the rotation groove to be axially rotatable a drive shaft bracket 420 provided on the inner bottom surface of the 230; and
A rotation member 430 that is configured to be rotatable in the vertical direction according to the withdrawal of the rod of the cylinder part 410 and is coupled to the hinge protrusion 131 while being disposed between the pair of drive shaft brackets 420 . );
Conductive sluice device provided with an eccentric roller rotating shaft, characterized in that it comprises a.
delete The method according to claim 1,
The load support roller part 310,
a load support bracket 311 provided at the upper end of the base 210 of the rotation guide 200;
an eccentric roller groove 312 having an angled cross-section and penetrating through the surface of the load support bracket 311; and
An eccentric roller 313 having an eccentric protrusion 314 protruding outward from an eccentric position on both sides of the roller and being inserted and fastened into the eccentric roller groove 312;
Conductive sluice gate device provided with an eccentric roller rotating shaft, characterized in that it comprises a.
10. The method of claim 9,
The eccentric projection 314 is,
Conduction provided with an eccentric roller rotation shaft, characterized in that it has a polygonal cross section made of a symmetrical shape, and the inner bottom surface of the eccentric roller groove 312 is formed to correspond to the polygonal shape of the eccentric protrusion 314 food sluice device.
10. The method of claim 9,
The guide rail part 320,
a rail bracket 321 provided on an upper side of the load support bracket 311 in a state in which a rail center groove 322 in which the rotation shaft of the eccentric roller 313 is rotatably disposed is formed on one upper side; and
a rail member 323 formed of a plate bent to have a predetermined radius and provided on the load support bracket 311;
Conductive sluice gate device provided with an eccentric roller rotating shaft, characterized in that it comprises a.
The method according to claim 1,
The guide roller part 330,
a guide bracket 331 protruding from the rear end side of the sluice part 100 to the rear side and provided with a pair of face-to-face faces, in which the upper end of the guide rail part 320 is disposed in the space therebetween;
a guide protrusion 332 protruding from the protruding end of the inner surface facing the guide bracket 331 in a direction facing each other;
a guide groove 333 into which the eccentric roller 313 is inserted;
a guide roller 334 provided to be axially rotatable on the front end of the guide protrusion 332 and configured to be guided along the lower surface of the rail member 323;
Conductive sluice gate device provided with an eccentric roller rotating shaft, characterized in that it comprises a.

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